JP2019128078A - Air conditioner - Google Patents

Abstract

To provide an air conditioner which can inhibit an effective heat transfer area from being reduced by water accumulating in a lower end part of a wet passage.SOLUTION: An air conditioner 100 is an indirect evaporative type air conditioner 100 and includes: a dry passage 21 in which cooled air A1 which is subjected to heat exchange with operation air A2 cooled by evaporation heat of water flows; and a wet passage 22 which is disposed adjacent to the dry passage 21 through a heat transmission partition wall 23 and has an inlet part 22a and an outlet part 22b opening in a vertical direction at an upper end part and in which the operation air A2 flows. The wet passage 22 is configured so as not to have a partition member for partitioning the passage in at least a lower part of its inner part.SELECTED DRAWING: Figure 4

Description

  The present invention relates to an air conditioner, and more particularly, to an indirect vaporization type air conditioner including a dry flow path and a wet flow path.

  Conventionally, an indirect vaporization type air conditioner including a dry flow path and a wet flow path is known (for example, see Patent Document 1).

  Patent Document 1 discloses an indirect vaporization type air conditioner including an indirect vaporization cooling element. The indirect evaporative cooling element of this air conditioner has a product air flow path (dry flow path) through which product air exchanged with the working air cooled by the heat of vaporization of water flows, and a working air flow through which working air flows. Road (wet flow path). The working air flow path has an inlet and an outlet of the working air at the upper end. Further, the working air flow path is supplied with water from a water spray nozzle disposed on the upper side with respect to the indirect vaporization cooling element. Further, inside the working air flow passage, three linear partition convex portions for dividing the flow passage are arranged in the vertical direction. By being partitioned by the three linear partition convex portions, four flow channels arranged in the vertical direction are formed inside the working air flow channel.

Japanese Patent Application Publication No. 2007-147117

  However, in the indirect evaporative cooling element of the air conditioner described in Patent Document 1, since the inside of the working air flow path is partitioned by the linear partitioning convex portion, each flow formed in the working air flow path is separated. The road narrows. Therefore, when the water from the water spray nozzle is accumulated at the lower end portion of the working air flow path and a part of the lowermost flow path partitioned by the lowermost linear partition convex portion is closed, the lowermost flow path Becomes too narrow. Since it becomes difficult for the working air to flow through the narrowest lowermost flow path, there is a problem that water is not sufficiently vaporized and an area contributing to heat transfer (effective heat transfer area) is reduced. Such a problem is particularly remarkable in a configuration in which the working air flow path has an inlet portion and an outlet portion at the upper end as in the air conditioner described in Patent Document 1 described above. In such a configuration, the water discharge port can not be secured at the lower end portion of the working air flow path, and thus water is likely to be accumulated at the lower end portion of the working air flow path.

  The present invention has been made to solve the problems as described above, and one object of the present invention is to reduce the effective heat transfer area due to the water collecting at the lower end of the wet flow path. It is providing the air conditioner which can suppress this.

  In order to achieve the above object, an air conditioner according to one aspect of the present invention is an indirect vaporization type air conditioner, which is a cooled air which is heat-exchanged with working air cooled by heat of vaporization of water. A dry flow path through which the air flows, and a wet flow path that is disposed adjacent to the dry flow path and the heat transfer partition, and that has an inlet portion and an outlet portion that open in the vertical direction at the upper end, and through which the working air flows. The wet flow path is configured so as not to have a partition member for partitioning the flow path at least in the lower part of the inside.

  In the air conditioner according to one aspect of the present invention, by configuring as described above, at least a part having no partition member in the lower part of the inside of the wet flow path is flown in the lower part of the inside of the wet flow path. The road can be widened. As a result, even if water is accumulated at the lower end portion of the wet flow channel, it is possible to suppress the flow channel from being excessively narrowed at the lower portion of the inside of the wet flow channel. As a result, it is possible to prevent the working air from becoming difficult to flow in the lower part of the inside of the wet flow path, and thus it is possible to prevent water from being sufficiently vaporized in the lower part of the inside of the wet flow path. can do. As a result, it is possible to provide an air conditioner that can suppress a reduction in the area contributing to heat transfer (effective heat transfer area) due to the accumulation of water at the lower end of the wet flow path. This effect is particularly effective in a configuration in which the wet flow path has an inlet portion and an outlet portion at the upper end portion and water tends to accumulate at the lower end portion, as in the air conditioner according to one aspect of the present invention. Furthermore, in the air conditioner according to one aspect of the present invention, the wet flow channel is configured not to have the partition member for partitioning the flow channel in at least the lower part of the inside, so that only the part without the partition member is provided. As the number of partition members can be reduced, the number of parts can be reduced, the structure can be simplified, and the number of assembling steps can be reduced.

  In the air conditioner according to the above aspect, the ratio of the length of the wet flow path in the flow direction of the working air substantially perpendicular to the vertical direction to the length of the wet flow path in the vertical direction is preferably 1.5 or less. is there. Thus, if the aspect ratio of the wet flow path is configured so as not to be horizontally long than 1.5, it is possible to prevent the wet flow path extending in the lateral direction from becoming excessively long in the flow direction. As a result, the working air can flow to the downstream side region of the wet flow path in the flow direction while maintaining a high flow velocity, so the working air flows in the downstream side region of the wet flow path in the flow direction. Generation of a difficult region can be suppressed as much as possible. As a result, the occurrence of deviation in the distribution of the flow velocity of the working air in the wet flow channel can be suppressed as much as possible, and thus the reduction of the effective heat transfer area can be further suppressed.

  In the air conditioner according to the above aspect, preferably, the opening length of the inlet of the wet flow passage or the opening length of the outlet of the wet flow passage with respect to the length of the wet flow passage in the flow direction of the working air substantially orthogonal to the vertical direction. The ratio is 0.1 or more and 0.3 or less. According to this structure, the inlet or the outlet of the wet channel can be prevented from being narrowed excessively, so that the flow velocity of the working air at the inlet or the outlet of the wet channel becomes excessively large. Can be suppressed. As a result, it is possible to suppress the occurrence of bias in the distribution of the flow speed of the working air inside the wet flow path due to the excessively large flow speed of the working air at the inlet or outlet of the wet flow path. . In addition, since it is possible to prevent the inlet or the outlet of the wet channel from becoming excessively wide, it is possible to suppress the flow velocity of the working air at the inlet or the outlet of the wet channel from becoming excessively small. it can. As a result, it is possible to suppress the occurrence of bias in the distribution of the flow speed of the working air inside the wet flow path due to the excessively small flow speed of the working air at the inlet or outlet of the wet flow path. .

  In the air conditioner according to the aforementioned aspect, preferably, a housing for accommodating the dry flow channel and the wet flow channel, and a housing are formed so that the working air flows in from the inlet of the wet flow channel, An inflow regulating member that regulates the flow; an outflow regulating member that is formed in the housing and regulates the flow of the working air so that the working air that has passed through the inside of the wet channel flows out from the outlet of the wet channel; The wet channel is configured not to have a partition member at the upper end for partitioning the channel. According to this structure, even if the wet flow passage does not have the partition member at the upper end, the inflow regulating member of the housing can reliably cause the working air to flow in from the inlet of the wet flow passage. The outflow restricting member allows the working air to be reliably discharged from the outlet of the wet flow passage. As a result, while maintaining the same flow of working air as in the case where the wet flow passage has the partition member at the upper end, the number of partition members can be further reduced by the amount not having the partition at the upper end. As the number of partition members is reduced, the number of parts can be reduced, the structure can be simplified, and the number of assembling steps can be reduced.

  In this case, preferably, a water supply unit is provided on the upper side with respect to the wet flow channel to supply water to the wet flow channel, and the wet flow channel is directly supplied with water from the water supply unit into the wet flow channel. Is configured. If comprised in this way, unlike the case where a wet flow path has a partition member in an upper end part, since the water from a water supply part is not blocked by the partition member of an upper end part, it is from a water supply part to the inside of a wet flow path. Water can be easily supplied directly.

  In the air conditioner according to the one aspect described above, preferably, a water supply unit that is provided above the wet flow path and supplies water to the wet flow path, and is provided below the wet flow path and passes through the wet flow path. A water retention portion that receives and retains water from the water supply portion, and the wet flow path is configured not to have a partition member for partitioning the flow path at the lower end portion. The lower end portion is immersed in water retained in the water retention portion. If comprised in this way, even if a wet flow path does not have a partition member in a lower end part, the water which retains in a water retention part can be functioned as a partition member of a lower end part. As a result, while maintaining the same flow of working air as in the case where the wet flow path has the partition member at the lower end, the number of partition members can be further reduced by the amount not having the partition at the lower end. As the number of partition members is reduced, the number of parts can be reduced, the structure can be simplified, and the number of assembling steps can be reduced.

  In addition, in this application, the following structures are also considered in the air conditioner by the said one situation.

  In the air conditioner according to the above aspect, the ratio of the length of the wet flow path in the flow direction of the working air substantially perpendicular to the vertical direction to the length of the wet flow path in the vertical direction is 1.2 or less. As described above, when the aspect ratio of the wet flow channel is not formed to be longer than 1.2, it is possible to suppress the wet flow channel extending in the lateral direction from becoming excessively long in the flow direction. As a result, the working air can flow to the downstream side region of the wet flow path in the flow direction while maintaining a high flow velocity, so the working air flows in the downstream side region of the wet flow path in the flow direction. Generation of a difficult region can be suppressed as much as possible. As a result, the occurrence of deviation in the distribution of the flow velocity of the working air in the wet flow channel can be suppressed as much as possible, and thus the reduction of the effective heat transfer area can be further suppressed. This effect has been confirmed by the present inventors through simulation.

  In the air conditioner according to the above aspect, preferably, the opening length of the inlet of the wet flow passage or the opening length of the outlet of the wet flow passage with respect to the length of the wet flow passage in the flow direction of the working air substantially orthogonal to the vertical direction. A ratio is 0.14 or more and 0.3 or less. According to this structure, the inlet or the outlet of the wet channel can be prevented from being narrowed excessively, so that the flow velocity of the working air at the inlet or the outlet of the wet channel becomes excessively large. Can be suppressed. As a result, it is possible to suppress the occurrence of bias in the distribution of the flow speed of the working air inside the wet flow path due to the excessively large flow speed of the working air at the inlet or outlet of the wet flow path. . In addition, since it is possible to prevent the inlet or the outlet of the wet channel from becoming excessively wide, it is possible to suppress the flow velocity of the working air at the inlet or the outlet of the wet channel from becoming excessively small. it can. As a result, it is possible to suppress the occurrence of bias in the distribution of the flow speed of the working air inside the wet flow path due to the excessively small flow speed of the working air at the inlet or outlet of the wet flow path. . This effect has been confirmed by the present inventors through simulation.

  According to the present invention, as described above, it is possible to suppress the effective heat transfer area from being reduced due to the accumulation of water at the lower end of the wet flow path.

1 is a schematic perspective view showing an air conditioner according to a first embodiment. It is a schematic sectional drawing along YZ plane which shows the air conditioner by 1st Embodiment. It is the typical side view which looked at the air-conditioner by 1st Embodiment from the Y direction. It is the figure which described the flow of working air and to-be-cooled air in FIG. It is a figure which shows the flow velocity distribution of the air in the air conditioner by an Example. It is a figure which shows the flow velocity distribution of the air in the air conditioning apparatus by a comparative example. It is the typical side view which looked at the air-conditioner by 2nd Embodiment from the Y direction. FIG. 7 is a diagram illustrating the flow of working air and air to be cooled.

  Hereinafter, an embodiment of the present invention will be described based on the drawings.

First Embodiment
The overall configuration of the air conditioner 100 according to the first embodiment will be described with reference to FIGS. 1 to 4. In the following description, the vertical direction is the Z direction. Further, directions substantially orthogonal to the Z direction and substantially orthogonal to each other in the horizontal plane are taken as an X direction and a Y direction, respectively.

(Configuration of air conditioner)
As shown in FIG. 1, the air conditioner 100 is an indirect vaporization type air conditioner that cools air by utilizing the vaporization phenomenon of water. The air conditioner 100 is installed for an air conditioning environment (not shown) such as a store and cools air in the air conditioning environment.

  The air conditioner 100 includes a housing 10, a core (indirect vaporization cooling element) 20, a blower fan 30, a water supply unit 40, and a water retention unit 50.

  In the housing 10, the core 20, the blower fan 30, the water supply unit 40, and the water retention unit 50 are housed. At the lower part of the housing 10, a dry air supply port 10a and a dry exhaust port 10b are provided. Both the dry air supply port 10a and the dry exhaust port 10b communicate with the air conditioning environment. The cooled air A1 warmed in the air-conditioned environment is sucked into the inside of the housing 10 via the dry air supply port 10a and supplied to the core 20. Further, a part of the cooled air A1 supplied to the core 20 and cooled by the core 20 (for example, about 50% to 80% air) is returned to the air-conditioned environment through the dry exhaust port 10b. As a result, the air conditioning environment is cooled. Further, the other part of the cooled air A1 supplied to the core 20 and cooled by the core 20 is supplied to a wet flow path 22 described later of the core 20 and is used as working air A2. In addition, the working air A2 that has passed through the wet flow path 22 is exhausted from the wet exhaust port 10c. The wet exhaust port 10 c is provided at the top of the housing 10 and communicates with the outside of the air conditioning environment. In addition, in FIG. 1, only a part of to-be-cooled air A1 which flows through the air conditioner 100, and working air A2 is shown for easy understanding.

  The core 20 cools the cooled air A1 supplied from the air-conditioned environment via the dry air supply port 10a of the housing 10. Specifically, as shown in FIG. 2, the core 20 includes a dry flow channel 21 and a wet flow channel 22. The core 20 has a structure in which the dry flow paths 21 and the wet flow paths 22 are alternately stacked in the Y direction. In the dry flow path 21, to-be-cooled air A1 which is heat-exchanged with the working air A2 cooled by the heat of vaporization of water flows. The working air A <b> 2 flows through the wet flow path 22. The dry flow passage 21 and the wet flow passage 22 are disposed adjacent to each other via the heat transfer partition 23. The dry flow passage 21, the wet flow passage 22, and the heat transfer partition 23 are all formed in a substantially rectangular shape when viewed from the Y direction. The details of the structures of the dry flow channel 21 and the wet flow channel 22 will be described later.

  The heat transfer partition wall 23 includes a cooled air A1 flowing through the dry flow path 21 and a working air A2 flowing through the wet flow path 22, and a cooled air A1 flowing through the dry flow path 21 and a working air A2 flowing through the wet flow path 22. They are separated so that heat can be exchanged between them. On the dry flow path 21 side of the heat transfer partition 23, a partition layer 23a which does not allow water to pass is formed. The partition layer 23a is made of, for example, a plate-like member made of resin (polypropylene or the like). Further, on the wet flow path 22 side of the heat transfer partition wall 23, a water retention layer 23b for retaining water from the water supply unit 40 is formed. The water retention layer 23 b is made of, for example, a non-woven fabric made of resin (such as polypropylene).

  Here, heat exchange between the air to be cooled A1 flowing through the dry flow path 21 and the working air A2 flowing through the wet flow path 22 will be described. When the working air A2 flows through the wet flow path 22, the water retained in the water retention layer 23b is vaporized by the working air A2 flowing through the wet flow path 22, and the heat transfer partition wall 23 is cooled. Further, heat exchange is performed between the air to be cooled A1 flowing through the dry flow path 21 and the working air A2 flowing through the wet flow path 22 via the heat transfer partition wall 23, and the air to be cooled A1 flowing through the dry flow path 21. Is cooled. The dry flow path 21 is separated from the water retention layer 23 b of the heat transfer partition wall 23 and the wet flow path 22 by a partition wall layer 23 a of the heat transfer partition wall 23 that does not allow water to pass through. For this reason, the air to be cooled A1 flowing through the dry flow path 21 is not humidified. As a result, the air to be cooled A1 flowing through the dry flow path 21 is cooled without being humidified and supplied from the dry exhaust port 10b of the housing 10 to the air-conditioned environment.

  As shown in FIG. 1, the blower fan 30 blows air toward the core 20. The blower fan 30 sends the to-be-cooled air A <b> 1 sucked into the inside of the housing 10 via the dry air supply port 10 a of the housing 10 to the dry flow path 21 of the core 20. The blower fan 30 is provided to face the core 20 on the side of the core 20 in the X2 direction.

  The water supply unit 40 supplies water to the wet flow path 22. The water supply unit 40 is configured by a sprayer, a water spray pipe such as a porous pipe. The water supply unit 40 is provided to face the core 20 on the upper side (Z1 direction side) with respect to the core 20. The water supply unit 40 supplies water (water sprinkling) to the wet flow path 22 of the core 20 and the water retention layer 23 b of the heat transfer partition 23 from the upper side of the core 20. The water from the water supply unit 40 permeates into the water retaining layer 23 b of the heat transfer partition 23 and is held by the water retaining layer 23 b. Further, the water from the water supply unit 40 flows from the upper side to the lower side (Z2 direction side) along the wet flow path 22 while soaking into the water retention layer 23b of the heat transfer partition wall 23. Part of the water flowing through the water retention layer 23b is vaporized by the working air A2. Of the water flowing through the water retaining layer 23b, the water that has not been vaporized by the working air A2 is discharged from the lower end of the water retaining layer 23b (the lower end of the core 20 and the wet channel 22).

  The water retention portion 50 receives and retains the water from the water supply portion 40 which has passed through the wet flow path 22 and the water retention layer 23 b of the heat transfer partition 23. The water retention portion 50 is constituted by, for example, a drain pan. The water retention portion 50 is provided to face the core 20 on the lower side (Z2 direction side) with respect to the core 20. The water retention portion 50 receives and stagnates water falling downward from the wet flow path 22 of the core 20 and the water retaining layer 23 b of the heat transfer partition 23. The water retained in the water retention portion 50 is discharged to the outside through a drain pipe (not shown). In addition, the water retention part 50 is arrange | positioned in the space divided from the distribution | circulation space of to-be-cooled air A1. For this reason, the water retention part 50 is comprised so that the to-be-cooled air A1 may not contact with the water surface of the water in which it flows from the dry air supply port 10a to the dry exhaust port 10b.

(Dry flow path and wet flow path)
As shown in FIGS. 1 and 2, the dry flow path 21 has an inlet portion 21a that opens in the X direction at the end portion on the X2 direction side, and an outlet portion 21b that opens in the X direction on the end portion on the X1 direction side. Have to. Cooled air A <b> 1 sucked into the housing 10 through the dry air inlet 10 a of the housing 10 and sent by the blower fan 30 flows into the inlet portion 21 a toward the X1 direction side. From the outlet 21b, the air to be cooled A1 cooled by the heat exchange with the working air A2 passing through the dry passage 21 and flowing through the wet passage 22 flows out toward the X2 direction.

  An upper end partition member 21c and a lower end partition member 21d are provided at the upper end portion and the lower end portion of the dry flow channel 21, respectively, for dividing the flow channel. The dry flow path 21 is partitioned by an upper partition member 21c, a lower partition member 21d, and two partition layers 23a of the heat transfer partition 23 facing each other in the Y direction. The upper partition member 21c, the lower partition member 21d, and the two partition layers 23a of the heat transfer partition 23 facing each other in the Y direction constitute the outermost peripheral portion of the dry flow path 21. The upper end partitioning member 21c and the lower end partitioning member 21d are made of, for example, a resin (vinyl chloride or the like) spacer formed in a linear shape extending along the X direction. The upper end partition member 21c and the lower end partition member 21d may be configured as the upper end portion and the lower end portion of the cardboard plastic.

  As shown in FIGS. 1-4, the wet flow path 22 has the inlet part 22a and the outlet part 22b which open to an up-down direction (Z direction) in an upper end part. The inlet 22a is provided at the upper end of the wet flow path 22 and at the end on the X1 direction side. A part of the air cooled by passing through the dry flow path 21 flows into the inlet portion 22a as the working air A2 toward the lower side (Z2 direction side). The outlet 22b is provided at the upper end of the wet flow path 22 and at the end on the X2 direction side. From the outlet portion 22b, the humidified working air A2 that passes through the wet flow path 22 flows out upward (Z1 direction side).

  An upper end partition member 22c, a lower end partition member 22d, and side end partition members 22e and 22f for partitioning the flow path are provided at the upper end portion, the lower end portion, and both end portions in the X direction of the wet flow channel 22, respectively. There is. The wet flow path 22 includes an upper end partition member 22c, a lower end partition member 22d, a side end partition member 22e, a side end partition member 22f, and two water retention layers 23b of the heat transfer partition 23 facing each other in the Y direction. It is divided. The upper end partition member 22c, the lower end partition member 22d, the side end partition member 22e, the side end partition member 22f, and the two water retention layers 23b of the heat transfer partition wall 23 facing each other in the Y direction are Construct the outermost part.

  The upper end partitioning member 22c and the lower end partitioning member 22d are made of, for example, resin spacers (vinyl chloride or the like) formed in a linear shape extending along the X direction. The side end partitioning member 22e and the side end partitioning member 22f are configured by, for example, a resin (vinyl chloride or the like) spacer formed in a linear shape extending in the vertical direction (Z direction). The upper end partition member 22c is shorter in the X direction than the lower end partition member 22d. An inlet portion 22a of the wet flow path 22 is provided between the end portion on the X1 direction side of the upper end partition member 22c that is short in the X direction and the upper end portion of the side end partition member 22e that is disposed apart in the X1 direction. Is formed. Similarly, between the end of the upper end partition member 22c, which is short in the X direction, on the X2 direction side, and the upper end of the side end partition member 22f arranged away from the end portion in the X2 direction, An outlet 22b is formed.

  Here, in the first embodiment, as shown in FIGS. 3 and 4, the wet flow path 22 is configured not to have a partition member for partitioning the flow path. The wet flow path 22 has a single flow path that does not branch, and is configured so that the working air A2 does not branch inside. The wet flow path 22 as a single flow path is configured such that the working air A2 flows in a substantially U shape when viewed from the Y direction. Specifically, in the wet flow path 22, the working air A2 flows in from the inlet portion 22a toward the lower side (Z2 direction side), and the inflowing working air A2 flows toward the X2 direction side. The working air A <b> 2 that has flowed through the outlet flows out from the outlet portion 22 b toward the upper side (Z1 direction side). While flowing in a substantially U shape, the working air A2 flows through the inside of the wet flow path 22 without branching.

  In addition, the wet flow path 22 has a substantially rectangular shape having a short side in the vertical direction (Z direction) and a long side in the X direction having a long side in the flow direction (X direction) of the working air A2 substantially orthogonal to the vertical direction. Have. The short side of the wet flow path 22 has a length L1. The length L1 is set to a length that is sufficiently higher than the height of the accumulated water even when water accumulates at the lower end portion (on the lower end partitioning member 22d) of the wet flow path 22. The length L1 has a size of about several hundred mm, for example. Further, the long side of the wet channel 22 has a length L2. The length L2 is set to such a length that the distribution of the flow velocity of the working air A2 is not very biased inside the wet flow path 22. The length L2 has a size of about several hundred mm, for example.

  In the first embodiment, the length L2 of the wet flow path 22 in the flow direction (X direction) of the working air A2 substantially orthogonal to the vertical direction with respect to the length L1 of the wet flow path 22 in the vertical direction (Z direction). Ratio (L2 / L1, aspect ratio) is 1.5 or less. Preferably, the ratio of the length L2 to the length L1 is 1.2 or less. As a ratio of the length L2 to the length L1, for example, about 1.2 can be set.

  Further, the inlet 22a of the wet flow passage 22 has an opening length L3. The opening length L3 is smaller than the length L1 and the length L2. The opening length L3 has a size of about several tens of millimeters, for example. Further, the outlet 22 b of the wet flow channel 22 has an opening length L4. The opening length L4 is smaller than the length L1 and the length L2. The opening length L4 has a size of about several tens of mm, for example. The opening length L3 and the opening length L4 are lengths (long side lengths) in the X direction of the substantially rectangular inlet and outlet portions 22a and 22b, respectively, and have substantially the same length.

  In the first embodiment, the ratio (L3 / L2 or L4 / L2) of the opening length L3 to the length L2 or the opening length L4 is 0.1 or more and 0.3 or less. Preferably, the ratio of the opening length L3 or the opening length L4 to the length L2 is 0.14 or more and 0.3 or less. As a ratio of the opening length L3 or the opening length L4 to the length L2, for example, about 0.14 can be set.

(Effect of the first embodiment)
In the first embodiment, the following effects can be obtained.

  In the first embodiment, as described above, the wet flow channel 22 is configured so as not to have a partition member for dividing the flow channel inside. As a result, the flow passage can be made wider inside the wet flow passage 22 by the amount not having the partition member. As a result, even if water is accumulated at the lower end portion of the wet flow channel 22, the flow channel can be prevented from being narrowed excessively inside the wet flow channel 22. Thereby, it is possible to prevent the working air A <b> 2 from becoming difficult to flow inside the wet flow path 22, and thus it is possible to prevent water from being sufficiently vaporized inside the wet flow path 22. As a result, it is possible to provide the air conditioner 100 that can suppress a reduction in the area (effective heat transfer area) contributing to heat transfer due to the accumulation of water at the lower end of the wet flow path 22. . The effect is that, like the air conditioner 100 according to one aspect of the present invention, the wet flow path 22 has an inlet 22a and an outlet 22b at the upper end, and water accumulates at the lower end (on the lower partition member 22d). This is particularly effective in an easy configuration. Furthermore, in the air conditioner 100 according to the first embodiment, the number of partition members is equal to that having no partition member by configuring the wet flow channel 22 so as not to have a partition member for dividing the flow channel inside. As the number of partition members is reduced, the number of parts can be reduced, the structure can be simplified, and the number of assembling steps can be reduced.

  Moreover, in 1st Embodiment, ratio L2 of the length of the wet flow path 22 in the distribution direction of the working air A2 substantially orthogonal to the up-down direction with respect to the length L1 of the wet flow path 22 in the up-down direction is set as described above. , 1.5 or less. By configuring the aspect ratio of the wet flow path 22 so as not to be a horizontally long shape than 1.5, the wet flow path 22 extending in the lateral direction is prevented from becoming excessively long in the flow direction. Can. As a result, the working air A2 can flow to the downstream side of the flow direction of the wet flow path 22 while maintaining a high flow velocity, so that the action is performed in the downstream side of the flow direction of the wet flow path 22 It is possible to minimize the occurrence of the area where the air A2 is hard to flow. Thereby, since it can suppress as much as possible that the distribution of the flow velocity of working air A2 arises inside the wet flow path 22, it can suppress more that an effective heat-transfer area becomes small. This effect has been confirmed by the present inventors through simulation.

  Further, in the first embodiment, as described above, the opening length L3 of the inlet portion 22a of the wet flow path 22 with respect to the length L2 of the wet flow path 22 in the flow direction of the working air A2 substantially orthogonal to the vertical direction or The ratio of the opening length L4 of the outlet 22b is configured to be 0.1 or more and 0.3 or less. Thereby, since it can suppress that the inlet part 22a or the outlet part 22b of the wet flow path 22 becomes narrow too much, the flow velocity of the working air A2 in the inlet part 22a or the outlet part 22b of the wet flow path 22 is excessive. It is possible to suppress the increase. As a result, the flow velocity distribution of the working air A2 is biased inside the wet flow channel 22 due to the excessively large flow velocity of the working air A2 at the inlet 22a or the outlet 22b of the wet flow channel 22. Can be suppressed. Moreover, since it can suppress that the inlet part 22a or the outlet part 22b of the wet flow path 22 becomes large too much, the flow velocity of the working air A2 in the inlet part 22a or the outlet part 22b of the wet flow path 22 is excessively small. It can be suppressed. As a result, the flow velocity distribution of the working air A2 is biased inside the wet flow channel 22 due to the excessively small flow velocity of the working air A2 at the inlet 22a or the outlet 22b of the wet flow channel 22. Can be suppressed. This effect has been confirmed by the present inventors through simulation.

[Example]
Next, an embodiment will be described with reference to FIGS. 5 and 6.

  As the air conditioner of the example, an air conditioner 100 having the structure of the first embodiment shown in FIG. 5 was used.

  Moreover, the air conditioner 100a which has a structure shown in FIG. 6 was used as an air conditioner of a comparative example. The air conditioner 100a of the comparative example is different from the air conditioner 100 of the example in that the wet flow path has an inlet portion at the lower end portion and an outlet portion at the upper end portion. 5 and 6, the reference numerals in the drawings are omitted for the convenience of illustration.

  Using the air conditioner 100 of the example and the air conditioner 100a of the comparative example, the flow velocity distribution inside the wet flow path was simulated.

In the simulation, simulation conditions were set to be the same except for differences in configuration between the air conditioner 100 of the embodiment and the air conditioner 100a of the comparative example. Specifically, in the simulation, the ratio L2 / L1 is set to 1.2, the ratios L3 / L2 and L4 / L2 are set to 0.14, and the dry flow path and the wet flow path are stacked (Y direction). The ratio of the air volume supplied to the wet flow path as the working air out of the cooled air that passed through the dry flow path is 2300 mm, the number of layers is about 150 layers, the supply air volume is 1300 m ³ / h Of 20% (that is, 260 m ³ / h).

  As shown in FIG. 5 and FIG. 6, the air conditioner 100 of the example is less biased in the distribution of the flow velocity of the working air in the wet flow path than the air conditioner 100 a of the comparative example, and the working air It can be seen that the distribution of the flow velocity is uniformed. In particular, in the central portion of the wet flow path, the distribution of the flow velocity is uniformed in the air conditioner 100 of the embodiment than in the air conditioner 100a of the comparative example. From this result, it can be seen that by providing the inlet portion and the outlet portion of the working air at the upper end portion of the wet flow path, it is possible to suppress the occurrence of bias in the distribution of the flow speed of the working air inside the wet flow path. Further, as described above, by appropriately setting the aspect ratio (L2 / L1) and the aperture ratio (L3 / L2 and L4 / L2), the wet flow can be obtained without providing the partition member inside the wet flow passage. It can be seen that it is possible to suppress the occurrence of deviation in the flow velocity distribution of the working air inside the passage. Moreover, as a result, it turns out that an effective heat transfer area can be enlarged.

Second Embodiment
Next, a second embodiment will be described with reference to FIGS. 7 and 8. In the second embodiment, unlike the first embodiment, an example in which the wet flow path does not have partition members for partitioning the flow path at the upper end and the lower end will be described. About the same composition as the 1st embodiment of the above, the same numerals are attached and illustrated in the figure, and the explanation is omitted.

(Configuration of air conditioner)
As shown in FIGS. 7 and 8, the air conditioner 200 according to the second embodiment has the above first embodiment in that the wet flow path 122 does not have partition members for partitioning the flow path at the upper end portion and the lower end portion. This is different from the air conditioner 100 of FIG.

  In 2nd Embodiment, the wet flow path 122 is a partition member for partitioning a flow path, Comprising: It does not have a partition member (upper end partition member 22c of the said 1st Embodiment) in an upper end part which comprises an outermost periphery part. Is configured. The wet flow path 122 is partitioned by a side end partition member 22e, a side end partition member 22f, and two water retaining layers 23b of the heat transfer partition 23 opposing each other in the Y direction.

  In the second embodiment, in the air conditioner 200, the inflow regulating member 111 that regulates the flow of the working air A2 and the working air A2 are wet such that the working air A2 flows in from the inlet 122a of the wet flow path 122 An outflow restricting member 112 is provided to restrict the flow of the working air A2 so as to flow out from the outlet portion 122b of the flow path 122. The inflow restricting member 111 and the outflow restricting member 112 are both formed in the housing 10 and extend along the vertical direction (Z direction) from the upper end of the housing 10 to the upper end of the wet flow path 122 Is formed. Further, the inflow regulating member 111 and the outflow regulating member 112 are disposed at positions facing each other in the X direction with the water supply portion 40 interposed therebetween. In the second embodiment, the inlet portion 122a of the wet flow path 122 is formed between the lower end portion of the inflow restricting member 111 and the upper end portion of the side end partitioning member 22e disposed away from the lower end portion in the X1 direction. It is done. Similarly, an outlet portion 122b of the wet flow path 122 is formed between the lower end portion of the outflow restricting member 112 and the upper end portion of the side end partitioning member 22f disposed away from the lower end portion in the X2 direction. .

  Further, in the second embodiment, the wet flow passage 122 is a partition member for dividing the flow passage, and the wet flow passage 122 from the water supply portion 40 is provided by not having the partition member constituting the outermost periphery at the upper end. It is comprised so that water may be directly supplied to the inside and the water retention layer 23b of the heat transfer partition wall 23.

  In the second embodiment, the wet flow path 122 is a partition member for partitioning the flow path, and has a partition member (the lower end partition member 22d in the first embodiment described above) at the lower end. It is configured not to. The lower end portion of the wet flow path 122 and the lower end portion of the water retaining layer 23b of the heat transfer partition 23 are immersed in water retained in the water retaining portion 50 from one end to the other end in the X direction. The water staying in the water retention part 50 is disposed at the lower end of the wet flow path 122 so that the working air A2 flowing inside the wet flow path 122 does not leak from the lower end of the wet flow path 122 to the outside of the wet flow path 122. It is comprised so that it may function as a partition member to partition.

  In addition, the other structure of 2nd Embodiment is the same as that of the said 1st Embodiment.

(Effect of the second embodiment)
In the second embodiment, the following effects can be obtained.

  In the second embodiment, as described above, the air conditioner 200 is formed in the casing 10, and the inflow that regulates the flow of the working air A2 so that the working air A2 flows from the inlet portion 122a of the wet flow path 122. An outflow restricting member which is formed in the restricting member 111 and the housing 10 and restricts the flow of the working air A2 so that the working air A2 which has passed through the inside of the wet flow path 122 flows out from the outlet portion 122b And 112. Then, the wet flow channel 122 is configured so as not to have a partition member for dividing the flow channel at the upper end. Thereby, even if the wet flow path 122 does not have a partition member at the upper end, the inflow restricting member 111 of the housing 10 can surely flow the working air A2 from the inlet portion 122a of the wet flow path 122. At the same time, the working air A2 can be reliably made to flow out from the outlet portion 122b of the wet flow path 122 by the outflow restricting member 112. As a result, while maintaining the flow of the working air A2 similar to the case where the wet flow path 122 has the partition member at the upper end, the number of partition members can be further reduced by the amount not having the partition at the upper end. In addition to the reduction in the number of partition members, the number of parts can be reduced, the structure can be simplified, and the number of assembling steps can be reduced.

  In the second embodiment, as described above, the wet flow path 122 is configured to be supplied directly from the water supply unit 40 to the inside of the wet flow path 122. Thus, unlike the case where the wet flow path 122 has a partition member at the upper end, water from the water supply unit 40 is not blocked by the partition member at the upper end, so that the water supply unit 40 enters the inside of the wet flow path 122. Water can be easily supplied directly.

  Moreover, in 2nd Embodiment, as mentioned above, the wet flow path 122 is comprised so that it may not have the partition member for partitioning a flow path in a lower end part. Then, the lower end portion of the wet flow path 122 is immersed in the water retained in the water retention portion 50. Thereby, even if the wet flow path 122 does not have a partition member in a lower end part, the water which retains in the water retention part 50 can be functioned as a partition member of a lower end part. As a result, while maintaining the flow of the working air A2 similar to the case where the wet flow path 122 has the partition member at the lower end, the number of partition members can be further reduced by the amount not having the partition at the lower end. In addition, the number of parts can be reduced, the structure can be simplified, and the number of assembly steps can be reduced as the number of partition members is reduced.

  The remaining effects of the second embodiment are similar to those of the aforementioned first embodiment.

[Modification]
It should be understood that the embodiments and examples disclosed herein are illustrative and non-restrictive in every respect. The scope of the present invention is shown not by the above description of the embodiments and examples but by the scope of claims for patent, and includes all modifications (modifications) within the meaning and scope equivalent to the scope of claims for patent.

  For example, in the first and second embodiments, an example is shown in which the air supply port (dry air supply port) and the exhaust port (dry exhaust port) for the air to be cooled are provided in the lower part of the housing. It is not restricted to this. In the present invention, it is not necessary to provide the air inlet and the air outlet of the air to be cooled in the lower part of the housing. The positions of the inlet and the outlet of the air to be cooled may be appropriately set according to the position of the air conditioner with respect to the air conditioning environment. For example, depending on the position of the air conditioner with respect to the air conditioning environment, the inlet and outlet for the cooled air may be provided on the side of the housing.

  Moreover, in the said 1st and 2nd embodiment, although the example which comprises a wet flow path so that it did not have a partition member for partitioning a flow path inside was shown, this invention is not limited to this. In this invention, the wet flow path should just be comprised so that it may not have the partition member for partitioning a flow path in the at least lower part of the inside. For this reason, the wet flow path may be configured to have a partition member for partitioning the flow path in the upper part of the inside.

  In the first and second embodiments, the ratio of the length L2 to the length L1 is 1.5 or less, but the present invention is not limited thereto. In the present invention, the ratio of the length L2 to the length L1 may be larger than 1.5, as long as the distribution of the flow velocity of the working air in the wet flow channel is not excessively distributed.

  In the first and second embodiments, the ratio of the length L3 to the length L2 or the length L4 is 0.1 or more and 0.3 or less. However, the present invention is not limited thereto. Absent. In the present invention, if the distribution of the flow velocity of the working air inside the wet flow path is not excessively biased, the ratio of the length L3 to the length L2 or the length L4 may be smaller than 0.1. It may be greater than 0.3.

DESCRIPTION OF SYMBOLS 10 Housing | casing 21 Dry flow path 22, 122 Wet flow path 22a, 122a Inlet part 22b, 122b Outlet part 23 Heat transfer partition 40 Water supply part 50 Water retention part 100, 200 Air-conditioning apparatus 111 Inflow regulation member 112 Outflow regulation member A1 Cooled Air A2 Working air L1 Length of the wet channel in the Z direction L2 Length of the wet channel in the X direction L3 Opening length of the inlet of the wet channel L4 Opening length of the outlet of the wet channel

Claims (6)

An indirect vaporization air conditioner,
A dry flow path through which to-be-cooled air which is heat-exchanged with working air cooled by the heat of vaporization of water;
The dry flow path and the heat transfer partition are arranged adjacent to each other, and have a wet flow path through which the working air flows, having an inlet portion and an outlet portion that open in the vertical direction at the upper end portion,
The air-conditioning apparatus according to claim 1, wherein the wet flow path is configured not to have a partition member for dividing the flow path at least a lower portion of the inside.   The air conditioning according to claim 1, wherein a ratio of a length of the wet flow passage in a flow direction of the working air substantially orthogonal to the vertical direction to a length of the wet flow passage in the vertical direction is 1.5 or less. apparatus.   The ratio of the opening length of the inlet of the wet flow passage or the opening length of the outlet to the length of the wet flow passage in the flow direction of the working air substantially orthogonal to the vertical direction is 0.1 or more The air conditioner according to claim 1 or 2, which is 0.3 or less. A housing that accommodates the dry channel and the wet channel;
An inflow restricting member which is formed in the housing and restricts the flow of the working air so that the working air flows in from the inlet of the wet flow passage;
An outflow regulating member that regulates the flow of the working air so that the working air that is formed in the housing and passes through the inside of the wet passage flows out of the outlet portion of the wet passage. ,
The air conditioning apparatus according to any one of claims 1 to 3, wherein the wet flow path is configured not to have a partition member for partitioning the flow path at an upper end portion. It further comprises a water supply unit provided on the upper side with respect to the wet flow channel and supplying water to the wet flow channel,
The air conditioner according to claim 4, wherein the wet flow passage is configured to be supplied with water directly from the water supply unit to the inside of the wet flow passage. A water supply unit provided on the upper side with respect to the wet flow channel and supplying water to the wet flow channel;
A water retention unit provided on the lower side with respect to the wet flow passage and configured to receive and retain water from the water supply unit that has passed through the wet flow passage,
The wet channel is configured not to have a partition member at the lower end for partitioning the channel,
The air conditioner according to any one of claims 1 to 5, wherein a lower end portion of the wet flow passage is immersed in water staying in the water retention portion.

Images